RU52878U1 - MULTI-LAYERED WALL-PROTECTING WALL DESIGN - Google Patents

Abstract

The utility model relates to construction, and more specifically, to multilayer enclosing wall structures, and can be used in the construction of buildings: as a supporting structure for low-rise buildings and as a self-supporting structure for high-rise buildings and structures. The multilayer enclosing wall structure contains an outer facing layer and an inner supporting layer interconnected by bonds, as well as a heat-insulating layer located between the outer and inner layers. It has any shape and profile, the outer facing layer is provided with a shotcrete layer on the inside, the inner carrier layer is made of reinforced shotcrete, and the bonds, mainly horizontally oriented, are made mainly in the form of rods, and are connected to the reinforced inner layer of shotcrete. The technical result is an increase in rigidity, stability and strength of the structure, as well as heat-insulating, waterproofing and frost-resistant indicators, improving its manufacturability, reducing the complexity and material consumption due to a more complete use of the strength properties of concrete and reinforcement, expanding functionality due to the possibility of varying the shape and profile of the structure , the choice of various concrete, type and material of the insulating layer with specified parameters.

Description

The utility model relates to construction, and more specifically, to multilayer enclosing wall structures, and can be used in the construction of buildings: as a supporting structure for low-rise buildings and as a self-supporting structure for multi-story buildings and structures.

Known heat-insulating reinforced panel containing two welded metal mesh, interconnected by flexible diagonal connections, and the middle layer of foam. This panel is intended for the construction of monolithic three-layer external walls of buildings [1].

A disadvantage of the known heat-insulating reinforced panel is the presence of a significant number of diagonal connections (more than 70 pcs / m ² ) between the grids necessary to achieve mounting rigidity, which leads to a significant decrease in thermal parameters. In addition, the known design provides for the use of only rigid types of insulation, as well as the use of lifting mechanisms and the inability to create a well-known heat-insulating reinforced panel in a building site due to the specifics of the process, which complicates it.

The closest in technical essence to the proposed design is the well-known three-layer wall containing a supporting inner layer, a layer of hard insulation and a facing layer of brick, connected to the supporting inner layer by means of metal brackets [2].

Common signs of the known and claimed devices are the presence of the outer facing layer and the inner bearing layer, interconnected by bonds, as well as a heat-insulating layer located between the outer and inner layers.

The disadvantages of the known device include limited functionality due to the requirement to use it only hard insulation, perceiving the active pressure of the wind and transmitting it to the main bearing layer, as well as limiting the height of the wall associated with different deformation of the bearing and facing layers and insufficient stability of the facing layer , which leads to insufficient rigidity of the structure and its thermal performance.

The utility model is based on the task of improving a multilayer enclosing wall structure, in which due to its generally different design with additional layers of shotcrete and bonds, it provides increased rigidity, stability and strength of the structure, as well as heat-insulating, waterproofing and frost-resistant indicators, improving its manufacturability, reduction of labor and material consumption due to a more complete use of the strength properties of concrete and reinforcement, expansion of functional possibilities due to the possibility of varying the shape and profile of the structure, the choice of various concrete, type and material of the heat-insulating layer with specified parameters, and due to this, solidity and high stability of the structure in installation and during operation are achieved, which leads to increased operational reliability and heat resistance of the structure, increase service life, as well as ensuring energy efficiency, which leads to lower costs for heating facilities made from the proposed blocks, and a reduction in installation time enclosing wall structure due to significant

reduction of small-sized building materials and its construction without the use of lifting mechanisms directly at the construction site.

This object is achieved in that the multilayer enclosing wall structure containing the outer cladding layer and the inner bearing layer interconnected by bonds, as well as the heat-insulating layer located between the outer and inner layers, according to the utility model, has any shape and profile, the outer facing layer it is provided with a layer of shotcrete on the inside, the inner bearing layer is made of reinforced shotcrete, and the bonds, mainly horizontally oriented, are made, mainly in the form of rods, and are connected to the reinforced inner layer of shotcrete.

In addition, in some certain cases, the implementation of the proposed multilayer enclosing wall structure is characterized by the following features: it is equipped with dowels formed by through holes in the insulating layer, filled with concrete, mainly shotcrete, and made mainly in the places of passage of the joints connecting the inner and outer layers; the bonds connecting the inner and outer layers are discrete; the shotcrete layer located on the inside of the facing layer is reinforced; the facing layer is made in the form of a stone layer in half a brick and has reinforcing elements; it is equipped with a vertical rack located in the insulating layer; the heat-insulating layer is made of any type and from any effective heat-insulating material, including completely from one material or a combination of several materials, depending on the purpose and operating conditions.

As a result of using the claimed utility model, a technical result is obtained consisting in

increasing rigidity, stability and strength of the structure, as well as heat-insulating, waterproofing and frost-resistant indicators, improving its manufacturability, reducing labor and material consumption due to more complete use of the strength properties of concrete and reinforcement, expanding functionality due to the possibility of varying the shape and profile of the structure, choosing different concrete, type and material of the insulating layer with specified parameters.

The proposed design due to the presence of distinctive essential features makes it possible to perform it of any shape and profile with the choice of the most effective material of the insulating layer, depending on the purpose and operating conditions, which expands the functionality when using it. The implementation of an additional layer of shotcrete on the inner side of the facing layer and the inner bearing layer of reinforced shotcrete in the presence of bonds, mainly horizontally oriented, connecting the inner and outer layers in the form of rods, and their connection with the reinforced inner layer of shotcrete, allows for monolithicity and increase rigidity, stability and strength of the structure, which leads to an increase in its operational reliability, as well as to ensure its adaptability during installation. At the same time, its waterproofing, heat-insulating and frost-resistant properties are increased, which leads to improved operational and consumer indicators. In addition, gunning ensures the absence of discrete connections when switching any architectural building systems, which allows you to create a walling of any shape and profile, which expands the functionality when using it. In General, the distinguishing features of the claimed device

are essential and necessary to achieve a new technical result.

According to the information available to the applicants, the set of essential features characterizing the essence of the claimed utility model is not known from the prior art, which allows us to conclude that it meets the criterion of "novelty." The inventive utility model can be repeatedly implemented in the construction of buildings and structures with the expected technical result, which allows us to conclude that it meets the criterion of "industrial applicability". Thus, the claimed utility model meets all the conditions of its patentability.

The essence of the utility model is illustrated by drawings, in which Fig. 1 shows a section of a multilayer enclosing wall structure with stone cladding applicable to load-bearing and self-supporting walls, and Fig. 2 shows a section of a multilayer enclosing wall structure with stone cladding for bearing walls with using various cases of its implementation.

The proposed multilayer enclosing wall structure can have any shape and profile, and contains (see figure 1): the outer facing layer 1, mainly stone, on the inside of which a layer of shotcrete is made 2. A heat-insulating layer 3 of any type adjoins it and from any effective heat-insulating material, including completely from one material or a combination of several materials, depending on the purpose and operating conditions. The material can be any lightweight effective insulation that has the specified properties (heat and sound insulation and other consumer qualities): structural or other effective heat insulation material, for example, polystyrene foam, polystyrene foam, foam glass, mineral wool or other composite materials. On the surface of the heat-insulating layer 3, an internal carrier is made

layer 4 of reinforced shotcrete facing the inside of the building. The type of concrete, the outer facing layer 1, its thickness and the thickness of the layers of shotcrete 2, 4 (for example, 30-60 mm) and heat-insulating layer 3 (for example, 100-200 mm) is regulated and selected depending on the required characteristics and designs of the walling . The outer facing 1 and the inner supporting 4 layers are interconnected by bonds 5, which are mainly horizontally oriented, and are made mainly in the form of rods of any design, cross-section and from any durable, mainly anti-corrosion material. For example, the rods have a diameter of 3-4 mm and are made of metal (stainless or galvanized steel), or of any composite material (fiberglass), which eliminates the corrosion of the rods at the boundaries between concrete and insulation layers. Moreover, the bonds 5 are rigidly connected to the reinforced inner supporting layer of shotcrete 4 and passed through the heat-insulating layer 3, the shotcrete layer 2 and the outer facing layer 1, where their ends are monolithic. The design has reliable hard contact (adhesion) of all layers, which ensures solidity and high stability during installation and operation, and also makes it possible to use small-weight wall structures. In addition, as examples of specific performance of a multilayer enclosing wall structure, it may have the following structural features (see figure 2). The design can be equipped with dowels 6 formed by through holes in the heat-insulating layer 3, filled with concrete, mainly shotcrete, and made mainly in the places of passage of bonds 5 connecting the inner 4 and outer 1 layers, which allows the thin-walled shell to form a joint rigid spatial structure . Connections 5 connecting inner 4 and

the outer 1 layers can be discrete, and the shotcrete layer 2 located on the inner side of the facing layer 1 can be reinforced. The outer facing layer 1 can be made, for example, in the form of a stone layer in half a brick, and to increase the stiffness, strength and reliability have reinforcing elements 7, such as mesh. The multilayer wall enclosure can be equipped with a vertical stand (not shown in the drawing) located in the heat-insulating layer, which allows to reduce its thickness, while maintaining rigidity, strength and reliability of the structure.

The proposed multilayer enclosing wall structure is erected directly on the construction site without the use of lifting mechanisms (cranes), which is its advantage compared to the known ones, which are traditionally manufactured in another place remote from construction, in the factory using special equipment, which leads to significant costs. The possibility of erecting the proposed enclosing wall structure on a construction site without using a crane together with the construction of the building allows not to delay the technological process, improve its manufacturability and reduce the installation time of the enclosing wall structure due to a significant reduction in small piece building materials, which generally significantly reduces the construction time of the entire building. When installing the proposed design, the outer facing layer 1 is first made of a given shape and profile. For example, in the form of a stone layer in half a brick with reinforcing elements 7 in the form of a grid and with the installation of rigid bonds 5 in the form of rods, mainly horizontally oriented. Subsequent construction work is carried out from within the building as follows. A layer of shotcrete is applied to the inner side of the facing layer 1. Then, installation or

applying a heat-insulating layer 3 - any effective insulation. Next, reinforcing mesh is attached to the rods 5 and other elements, followed by applying a layer of shotcrete on it, as a result of which an inner supporting layer 4 of reinforced shotcrete is formed. This ensures the design position of the insulating layer 3 and other layers. Thus, the possibility of layer-by-layer construction of the proposed enclosing wall structure allows it to be made of any shape and profile, i.e. make switching of any architectural building systems. To further increase the rigidity and strength of the structure (see figure 2) in the heat-insulating layer 4, in the places of passage of the bonds 3 connecting the inner 2 and outer 1 layers, through holes are made, which are then filled with concrete, mainly shotcrete, due to which dowels 6. Or, when performing a shotcrete layer 2, which is located on the inner side of the facing layer 1, it is reinforced using, for example, reinforcing mesh 7. If necessary, reduce the thickness of the structure in heat zolyatsionnom layer 3 has a vertical rack (not shown). As you can see, the proposed multilayer enclosing wall structure works as a thin-walled stable shell and, depending on applicability, has a different degree of commutation when forming a spatial structure, which allows it to be made of any shape and profile according to the design. In the used technological approach, based on the possibility of vertical concrete application by a mechanized method, a wall structure is formed with optimal indicators both from the positions of thermal, technological, economic and operational, fully meeting the new trends of the industrial construction concept.

The proposed technical solution in comparison with the prototype has the following advantages: obtaining a multilayer enclosing wall structure with predetermined qualities of any shape and profile with improved operational and consumer qualities, which allows it to be used for various projects and in different climatic conditions; providing a monolithic structure of increased strength and stability in installation and during operation, as well as its construction directly at the construction site without the use of lifting mechanisms; the ability to solve complex problems of walling of building structures and structures.

Based on this utility model, prototypes were manufactured that underwent tests confirming the feasibility and obtaining the expected technical result and positive effect.

The proposed multilayer enclosing wall structure can find application in the construction of buildings of any number of storeys.

Information sources.

1. The magazine "Architecture and Construction of Belarus". - ed. "Fire". - 1992. - No. 2. - C.11-12.

2. Butovsky NN, Khudoshina OV Improving the design solutions of thermal protection of the exterior walls of buildings. - M .: VNIINTPI. - 1990. - S.60 (prototype).

Claims (7)

1. A multilayer enclosing wall structure comprising an outer facing layer and an inner supporting layer interconnected by bonds, as well as a heat-insulating layer located between the outer and inner layers, characterized in that it has any shape and profile, the outer facing layer on the inside equipped with a shotcrete layer, the inner carrier layer is made of reinforced shotcrete, and the bonds, mainly horizontally oriented, are made mainly in the form of rods, and are connected to reinforced inner layer of shotcrete. 2. The multilayer enclosing wall structure according to claim 1, characterized in that it is provided with dowels formed by through holes in the heat-insulating layer, filled with concrete, mainly shotcrete, and made mainly in the places of passage of joints connecting the inner and outer layers. 3. The multilayer enclosing wall structure according to claim 1, characterized in that the bonds connecting the inner and outer layers are discrete. 4. The multilayer enclosing wall structure according to claim 1, characterized in that the shotcrete layer located on the inside of the facing layer is reinforced. 5. The multilayer enclosing wall structure according to claim 1, characterized in that the facing layer is made in the form of a stone layer in half a brick and has reinforcing elements. 6. The multilayer enclosing wall structure according to claim 1, characterized in that it is equipped with a vertical rack located in the insulating layer. 7. The multilayer enclosing wall structure according to claim 1, characterized in that the heat-insulating layer is made of any type and of any effective heat-insulating material, including completely from one material or a combination of several materials, depending on the purpose and operating conditions.